Correlation of Cl35 Nuclear Quadrupole Coupling Frequencies with

By Harlan C. Meal. Received September 4, 1952. The nuclear quadrupole resonance frequency for. Cl36 has been measured for some chlorobenzene...
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NOTES

Dec. 5 , 1952 from ethanol. If the substance remained liquid (generally a heavy oil), it was extracted with ether, the extract dried over magnesium sulfate, and warmed to remove the solvent. The resulting residue was distilled under diminished pressure. Picrates.-The picrates of the azomethines were prepared by adding a saturated solution of picric acid in either ethanol or benzene to a solution of about 0.2 g. of the base in the same solvent. The crude picrates were recrystallized from glacial acetic acid (except as noted in the table). DEPARTMENT OF CHEMISTRY BOSTONCOLLEGE CHESTNUT HILL,MASSACHUSETTS

6121

\

0-CF,

-

35.0

m-COOH m-CF,

p-OCH,

Correlation of C136 Nuclear Quadrupole Coupling Frequencies with Hamrnett's Sigma' BY HARLAN C. MEAL 4, 1952 RECEIVED SEPTEMBER

The nuclear quadrupole resonance frequency for

C136 has been measured for some chlorobenzene derivatives with a frequency modulated superregenerative spectrometer2 (Table I). Signals TABLE I

Benzyl

C136 NUCLEARQUADRUPOLE INTERACTION FREQUENCIES OBSERVEDIX VARIOUS SUBSTITUTEDCHLOROBESZENE COMPOUNDS

,

50

0x1

m-NOa m-COOH m-CFs m-CI

$-OH m-N=C=Ob #-OCHI o-N=C=Ob None p-c1 9-COOH p-COCHi p-CHO P-CHzCI P-OCzHs P-NKa p-CH=CHCOOH Benzyl chloride

19GOK. 36.997 mc." 35.683 35.496" 35.424' 35.278" 35. 215" 35.225" 35.053 34.632 34.732" 34,724" 34.523" 34.503" 34.672" 34.4340 34.653 34.433 34.415 34. 026" 34.562" 34.471 34.327 34.381 34.403 34.303 32.840 34.180 33.974" 34.227 32.417

37.47 mc.

f2.030

35.824 35.755 35.755 35.580 35.457 35.227 35.073 35.030 35.030 34,875 34.809 34.945" 34,700"

35.97 35,92 35.97 35.75 35.60 35.26 35.23 35.20 35.20 35.09 34.96 35.19 34.82

4-1.260

34.753

34.94

34.622" 34.7794 34.673 34.618 34.607 34.623 34.567 33.754 34.381 34.146"

34.90 34.88 34.78 34.73 34.67 34.68 34.69 34.24 34.44 34.20 34.40 34.14

33.630

+0.710

.373

-

,317

-

.268

300

375.

+ .355 + .42" +

250

OK

Fig. 1.

c

37,260 mc.

200

I50

Tarnparafurs

p-CH2CI I

I

100

ClJ5 frequency at Substitilent o-NOI o-CFib

Chloride/*\ \

370-

36.5-

36.0u

0.00

+ .227

C .728 4- ,874 4-1.126 +0.025

-

.25 .660 4- .619

-

Data from Dean and Pound (private communication). b Observations not yet complete, also, no U-values available. 0 J. D. Roberts, R. L. Webb and E. A. McElhill, THIS JOURNAL, 72, 408 (1950).

too weak to be detected with frequency modulation and oscilloscope display were observed using magnetic field modulation, phase-sensitive detection and pen recording. Temperature dependences of the frequencies were determined (Fig. 1) and extrapolated to absolute zero. These, together with the data of Dean and Pound similarly extrapolated, (1) The research reported in this paper was made possible by support extended Harvard University by the ONR under Contract N5ori 76, Task Order V. (2) C . Dean and R. V. Pound, J . Chrm. Phys., 20, 195 (1952).

.5 35 5 u .a I

LL F35

0-

+

n E

p-COCH

QP. 34 5-

Vp-CH-CHCOON

34t -1.0

I

-0.5

I

I

0.5

0.0

1.0

1.5

2.0

0-

Fig. 2.

have been plotted against Hammett's substituent parameter sigma3 (Fig. 2 ) . Limits of error assigned are the mean deviations given by Hammett or arbitrarily taken to be 0.1 unit for sigma; for the frequencies the expected maximum error in the extrapolation is used. Where crystallographically non-equivalent chlorines give rise to multiple lines the frequencies of the several lines are plotted. (3) L. P. Hammett. "Physical Organic Chemistry," McGraw-Hill

Book Co., Inc.. New York, N. Y..1040, Chap. VII.

6121,

NOTES

In the case of p-chlorobenzyl chloride it is thought that the two lines arise from the two chemically different chlorines in the molecule. The higher frequency was assigned to the chlorine on the ring on the basis of the result obtained with benzyl chloride. u-Values for the ortho substituents were calculated from the ionization constants of the corresponding benzoic acids, for p-CH2Cl from nuclear nitration data,315 for p-OH from the ionization constant of p-hydroxybenzoic acid.6 The work of Taft indicates that obtaining ortho U-values in this fashion is a dubious procedure7 although the fit is satisfactory. Further work with ortho substituted chlorobenzene compounds may help elucidate the polar effects of such substituents. One might expect a relation to exist between the resonance frequency and sigma since the latter is a nieasure of the electron density a t a given carbon atom in the ring3 and the quadrupole frequency is closely related to the location of bonding electrons.8 Solid state influences might upset this relation but these are apparently relatively constant in the present compounds. In iodine8 and chloral hydrates they cause larger deviations. The U-values assigned to the substituents 9CHO, P-COCHB, p-COOH and p-CH=CHCOOH are probably too large as a result of resonance stabilization of the phenoxide ion in the experinients used to determine those values.'O Hamniett states that these values are probably only valid for phenol and aniline derivatives. There is a wider difference between the meta and para values for these compounds than for compounds in which resonance is blocked. The same resonance effects in the chlorine substituted molecule might be expected to diminish the quadrupole frequency by increasing the double bond character of the C-C1 bond. The deviation of the *-OH substituent may arise from hydrogen bonding of the chlorine through the hydroxyl of an adjacent molecule as in chloral h ~ d r a t e . ~ Also the a-value assigned to the hydroxyl group is not well defined." The deviation of the p-OCH, compound is unexplained. The ClS6 quadruple frequency in p-deuterochlorobenzene has been observed to be equivalent, within experimental error (4kc.), to that in chlorobenzene. The author would like to express his appreciation to Professor E. Bright Krilson, Jr., who suggested this research and lent valuable assistance in discussions, to Professor J. D. Roberts of M. I. T., who supplied the p-chlorocinnamic acid, the 0- and the m-chlorobenzotrifluorides, and for several valuable (4) J. F. J. Dippy arid R . H . Lewis, J . Chem. Soc., 343 (1935); J . 1,'. J. Dippy, F. R . Williams and R . H. I.ewis, i b i d . , 1426 (1937). (5) C. K. Ingold, et ol., ibid., 675 (1949); 905, 918, 929 (1938); 1959 (1931). (6) G. E. K. Branch and D . L. Yabroff,THISJ O U R N A L , 66, 2668

(1934).

(7) R. W. Taft, Jr., i b i d . , 74, 2729, 3120 (1952). (8) C. H. Townes and B. P. Dailep. J . Chem. Phyr., 20, 35 (1952). (9) H. C. Allen, THISJOURNAL, 74, 6074 (1952). (10) G. N. Burkhardt, C. Horrex and D. 1. Jenkins, J. Chem. Soc., 1654 (1936); G. N. Burkhardt, W. G. K . Ford and E. Sinnleton, i b i d . , 17 (1936). (11) E. Berliner and I.. C. Monack, THISJ O U R N A L , 74, 167-1 (1952).

Vol. 74

suggestions, to Dr. Christopher Dean for considerable help with the instrumentation, to Miss Janet Hawkins who supplied the p-deuterochlorobenzene, and to Dr. Harry C. Allen, Jr., for constant advice and encouragement. MALLINCKRODT CHEMICAL LABORATORY HARVARD UNIVERSITY MASS. CAMBRIDGE.

Preparation of Radiohypophosphate Ion B Y THERALD LIOELLER AVD

RECEIVED JUXE

GLADYS H. 20, 1952

QUIST'i

In conjunction with investigations on the hypophosphates of thorium and the rare earth elements,' hypophosphate ion (Pz06-4) containing phosphorus32 was required. This was best prepared as the disodium dihydrogen salt by the direct oxidation of elemental radiophosphorus with sodium chlorite by an adaptation of the procedure of Leininger and ChulskL2 Attempted preparations involving exchange of inactive hypophosphate with radioorthophosphate and with radiopyrophosphate gave negative results, in keeping with other observat i o n ~ ~ - 'upon the general absence of exchange among the oxidation states of phosphorus. Experimental Chlorite Oxidation of Radiophosphorus.-One-gram samples of red phosphorus were sealed in evacuated quartz tubes and irradiated in the pile at the Oak Ridge Sational Laboratories. As received after irradiation, these samples had activities approaching 50 millicuries per gram of phosphorus. The tubes were opened in a dry-box in a carbon dioxide atmosphere by cutting grooves around the tips with a small emery wheel, continuing grinding until small holes developed to admit carbon dioxide, and then cracking off the tips. Each sample of active phosphorus was then mixed thoroughly with 25 g. of inactive red phosphorus. The mixed solids were converted by chlorite oxidation to disodium dihydrogen hypophosphate 6-hydrate as described by Leininger and Chulski.2 To obviate losses and reduce contamination hazards, the reaction vessel was of Pyrex with the central tube sealed in. Connection t o the receiving flask was made with Tygon tubing. Both reaction vessel and receiving flask were surrounded by '/*-in. lead sheeting, and all operations were conducted in well-ventilated hoods with ample precautions taken to prevent radiation hazards. The preparations proceeded as described,* yielding products of high purity and activity. The high-activity waste liquors which accumulated were stored in lead-shielded containers until activities had decreased to safe levels before disposal. Attempted Orthophosphate-Hypophosphate Exchange.Radiophosphoric acid, obtained from the Oak Ridge National Laboratories, was diluted with 0.1 M sodium dihydrogen orthophosphate solution to an activity of some 5000 counts per minute per milliliter. Equal aliquots of this solution and of a 0.1 M disodium hypophosphate solution were mixed, adjusted to pH 1, 5 and 10 and temperature equilibrated a t 2 5 , 60 and 90". At various time intervals, 2-rnl. samples were withdrawn, diluted with 2 ml. of 12 AJ hydrochloric acid, and treated with a few drops of concentrated thorium nitrate solution (7 g. of the salt in 50 ml.). Under these conditions, only thorium hypophosphate is precipitated,' and precipitation of thorium is quantitative. (1) 1951. (2) (3) (4) (6) (6)

G. H. Quinty, Doctoral Dissertation, University of Illinois,

E. Lrininger and T . Chulski, THISJOURNAL, 71, 2385 (1949). J. N. Wilson, i b i d . , BO, 2697 (1938). C. Perrier and E. SegrP, Rirercu sci., 9 , I, 638 (1938). D . E. Hull, TIIISJOURNAL, 63, 1269 (1941). R. C. Vogel and N. Podall, i b i d . , 72, 1420 (1950). (7) V. D. Ionin, -4.F.Lukovnikov. hI. B. Xeiman and A n . N. Nesmeyanov, Doklady A k u d . Xauk S.S.S.R., 67, 463 (1949).